Fail-safe synchronization circuit for duplicated systems

Proceedings 2001 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems Pub Date : 2001-10-24 DOI:10.1109/DFTVS.2001.966795

E. Kolonis, M. Nicolaidis

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引用次数: 2

Abstract

Actuators in safety critical systems must be driven by fail-safe signals. Under a failure in the system, such a signal must be either correct or on the safe state (e.g. red colour in traffic control lights). To achieve the fail-safe property, processors controlling such actuators use hardware and/or software redundancy (e.g. duplicated processors, software coding techniques). Each of the signals delivered by such a system must be fail-safe individually in order to drive an actuator. To create such signals, one has to use an interface that transforms the redundant signals delivered by the control processor into fail-safe signals. This can be performed by a fail-safe interface. The present work treats the case where the inputs of the interface are delivered by a duplicated system. To avoid common mode failures the two copies of the system do not share hardware resources. Thus, they use different clocks, and the two system copies are not mutually synchronized at clock cycle level. Any attempt to synchronise them will require to share some resources and will introduce common mode failures. This work proposes a circuit that transforms two copies of non-synchronised signals into synchronised signals, while at the same time preserves the safety of the system under the introduced common mode failures.

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用于重复系统的故障安全同步电路

安全关键系统中的执行器必须由故障安全信号驱动。在系统发生故障时，这样的信号必须是正确的或处于安全状态(例如交通管制灯的红色)。为了实现故障安全特性，控制此类执行器的处理器使用硬件和/或软件冗余(例如，重复处理器，软件编码技术)。为了驱动执行器，这种系统所传递的每个信号都必须是独立的故障安全的。要创建这样的信号，必须使用一个接口，将控制处理器传递的冗余信号转换为故障安全信号。这可以通过故障安全接口执行。目前的工作处理的情况下，接口的输入是由一个重复的系统交付。为避免共模故障，系统的两个副本不共享硬件资源。因此，它们使用不同的时钟，并且两个系统副本在时钟周期级别上不会相互同步。任何同步它们的尝试都需要共享一些资源，并将引入公共模式故障。这项工作提出了一种电路，将非同步信号的两个副本转换为同步信号，同时在引入的共模故障下保持系统的安全性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings 2001 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems

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